void Ekf2::task_main() { // subscribe to relevant topics int sensors_sub = orb_subscribe(ORB_ID(sensor_combined)); int gps_sub = orb_subscribe(ORB_ID(vehicle_gps_position)); int airspeed_sub = orb_subscribe(ORB_ID(airspeed)); int params_sub = orb_subscribe(ORB_ID(parameter_update)); int optical_flow_sub = orb_subscribe(ORB_ID(optical_flow)); int range_finder_sub = orb_subscribe(ORB_ID(distance_sensor)); int ev_pos_sub = orb_subscribe(ORB_ID(vehicle_vision_position)); int ev_att_sub = orb_subscribe(ORB_ID(vehicle_vision_attitude)); int vehicle_land_detected_sub = orb_subscribe(ORB_ID(vehicle_land_detected)); int status_sub = orb_subscribe(ORB_ID(vehicle_status)); px4_pollfd_struct_t fds[2] = {}; fds[0].fd = sensors_sub; fds[0].events = POLLIN; fds[1].fd = params_sub; fds[1].events = POLLIN; // initialise parameter cache updateParams(); // initialize data structures outside of loop // because they will else not always be // properly populated sensor_combined_s sensors = {}; vehicle_gps_position_s gps = {}; airspeed_s airspeed = {}; optical_flow_s optical_flow = {}; distance_sensor_s range_finder = {}; vehicle_land_detected_s vehicle_land_detected = {}; vehicle_local_position_s ev_pos = {}; vehicle_attitude_s ev_att = {}; vehicle_status_s vehicle_status = {}; while (!_task_should_exit) { int ret = px4_poll(fds, sizeof(fds) / sizeof(fds[0]), 1000); if (ret < 0) { // Poll error, sleep and try again usleep(10000); continue; } else if (ret == 0) { // Poll timeout or no new data, do nothing continue; } if (fds[1].revents & POLLIN) { // read from param to clear updated flag struct parameter_update_s update; orb_copy(ORB_ID(parameter_update), params_sub, &update); updateParams(); // fetch sensor data in next loop continue; } else if (!(fds[0].revents & POLLIN)) { // no new data continue; } bool gps_updated = false; bool airspeed_updated = false; bool optical_flow_updated = false; bool range_finder_updated = false; bool vehicle_land_detected_updated = false; bool vision_position_updated = false; bool vision_attitude_updated = false; bool vehicle_status_updated = false; orb_copy(ORB_ID(sensor_combined), sensors_sub, &sensors); // update all other topics if they have new data orb_check(status_sub, &vehicle_status_updated); if (vehicle_status_updated) { orb_copy(ORB_ID(vehicle_status), status_sub, &vehicle_status); } orb_check(gps_sub, &gps_updated); if (gps_updated) { orb_copy(ORB_ID(vehicle_gps_position), gps_sub, &gps); } orb_check(airspeed_sub, &airspeed_updated); if (airspeed_updated) { orb_copy(ORB_ID(airspeed), airspeed_sub, &airspeed); } orb_check(optical_flow_sub, &optical_flow_updated); if (optical_flow_updated) { orb_copy(ORB_ID(optical_flow), optical_flow_sub, &optical_flow); } orb_check(range_finder_sub, &range_finder_updated); if (range_finder_updated) { orb_copy(ORB_ID(distance_sensor), range_finder_sub, &range_finder); if (range_finder.min_distance > range_finder.current_distance || range_finder.max_distance < range_finder.current_distance) { range_finder_updated = false; } } orb_check(ev_pos_sub, &vision_position_updated); if (vision_position_updated) { orb_copy(ORB_ID(vehicle_vision_position), ev_pos_sub, &ev_pos); } orb_check(ev_att_sub, &vision_attitude_updated); if (vision_attitude_updated) { orb_copy(ORB_ID(vehicle_vision_attitude), ev_att_sub, &ev_att); } // in replay mode we are getting the actual timestamp from the sensor topic hrt_abstime now = 0; if (_replay_mode) { now = sensors.timestamp; } else { now = hrt_absolute_time(); } // push imu data into estimator float gyro_integral[3]; gyro_integral[0] = sensors.gyro_rad[0] * sensors.gyro_integral_dt; gyro_integral[1] = sensors.gyro_rad[1] * sensors.gyro_integral_dt; gyro_integral[2] = sensors.gyro_rad[2] * sensors.gyro_integral_dt; float accel_integral[3]; accel_integral[0] = sensors.accelerometer_m_s2[0] * sensors.accelerometer_integral_dt; accel_integral[1] = sensors.accelerometer_m_s2[1] * sensors.accelerometer_integral_dt; accel_integral[2] = sensors.accelerometer_m_s2[2] * sensors.accelerometer_integral_dt; _ekf.setIMUData(now, sensors.gyro_integral_dt * 1.e6f, sensors.accelerometer_integral_dt * 1.e6f, gyro_integral, accel_integral); // read mag data if (sensors.magnetometer_timestamp_relative == sensor_combined_s::RELATIVE_TIMESTAMP_INVALID) { // set a zero timestamp to let the ekf replay program know that this data is not valid _timestamp_mag_us = 0; } else { if ((sensors.timestamp + sensors.magnetometer_timestamp_relative) != _timestamp_mag_us) { _timestamp_mag_us = sensors.timestamp + sensors.magnetometer_timestamp_relative; // If the time last used by the EKF is less than specified, then accumulate the // data and push the average when the 50msec is reached. _mag_time_sum_ms += _timestamp_mag_us / 1000; _mag_sample_count++; _mag_data_sum[0] += sensors.magnetometer_ga[0]; _mag_data_sum[1] += sensors.magnetometer_ga[1]; _mag_data_sum[2] += sensors.magnetometer_ga[2]; uint32_t mag_time_ms = _mag_time_sum_ms / _mag_sample_count; if (mag_time_ms - _mag_time_ms_last_used > _params->sensor_interval_min_ms) { float mag_sample_count_inv = 1.0f / (float)_mag_sample_count; float mag_data_avg_ga[3] = {_mag_data_sum[0] *mag_sample_count_inv, _mag_data_sum[1] *mag_sample_count_inv, _mag_data_sum[2] *mag_sample_count_inv}; _ekf.setMagData(1000 * (uint64_t)mag_time_ms, mag_data_avg_ga); _mag_time_ms_last_used = mag_time_ms; _mag_time_sum_ms = 0; _mag_sample_count = 0; _mag_data_sum[0] = 0.0f; _mag_data_sum[1] = 0.0f; _mag_data_sum[2] = 0.0f; } } } // read baro data if (sensors.baro_timestamp_relative == sensor_combined_s::RELATIVE_TIMESTAMP_INVALID) { // set a zero timestamp to let the ekf replay program know that this data is not valid _timestamp_balt_us = 0; } else { if ((sensors.timestamp + sensors.baro_timestamp_relative) != _timestamp_balt_us) { _timestamp_balt_us = sensors.timestamp + sensors.baro_timestamp_relative; // If the time last used by the EKF is less than specified, then accumulate the // data and push the average when the 50msec is reached. _balt_time_sum_ms += _timestamp_balt_us / 1000; _balt_sample_count++; _balt_data_sum += sensors.baro_alt_meter; uint32_t balt_time_ms = _balt_time_sum_ms / _balt_sample_count; if (balt_time_ms - _balt_time_ms_last_used > (uint32_t)_params->sensor_interval_min_ms) { float balt_data_avg = _balt_data_sum / (float)_balt_sample_count; _ekf.setBaroData(1000 * (uint64_t)balt_time_ms, balt_data_avg); _balt_time_ms_last_used = balt_time_ms; _balt_time_sum_ms = 0; _balt_sample_count = 0; _balt_data_sum = 0.0f; } } } // read gps data if available if (gps_updated) { struct gps_message gps_msg = {}; gps_msg.time_usec = gps.timestamp; gps_msg.lat = gps.lat; gps_msg.lon = gps.lon; gps_msg.alt = gps.alt; gps_msg.fix_type = gps.fix_type; gps_msg.eph = gps.eph; gps_msg.epv = gps.epv; gps_msg.sacc = gps.s_variance_m_s; gps_msg.vel_m_s = gps.vel_m_s; gps_msg.vel_ned[0] = gps.vel_n_m_s; gps_msg.vel_ned[1] = gps.vel_e_m_s; gps_msg.vel_ned[2] = gps.vel_d_m_s; gps_msg.vel_ned_valid = gps.vel_ned_valid; gps_msg.nsats = gps.satellites_used; //TODO add gdop to gps topic gps_msg.gdop = 0.0f; _ekf.setGpsData(gps.timestamp, &gps_msg); } // only set airspeed data if condition for airspeed fusion are met bool fuse_airspeed = airspeed_updated && !vehicle_status.is_rotary_wing && _arspFusionThreshold.get() <= airspeed.true_airspeed_m_s && _arspFusionThreshold.get() >= 0.1f; if (fuse_airspeed) { float eas2tas = airspeed.true_airspeed_m_s / airspeed.indicated_airspeed_m_s; _ekf.setAirspeedData(airspeed.timestamp, airspeed.true_airspeed_m_s, eas2tas); } // only fuse synthetic sideslip measurements if conditions are met bool fuse_beta = !vehicle_status.is_rotary_wing && _fuseBeta.get(); _ekf.set_fuse_beta_flag(fuse_beta); if (optical_flow_updated) { flow_message flow; flow.flowdata(0) = optical_flow.pixel_flow_x_integral; flow.flowdata(1) = optical_flow.pixel_flow_y_integral; flow.quality = optical_flow.quality; flow.gyrodata(0) = optical_flow.gyro_x_rate_integral; flow.gyrodata(1) = optical_flow.gyro_y_rate_integral; flow.gyrodata(2) = optical_flow.gyro_z_rate_integral; flow.dt = optical_flow.integration_timespan; if (PX4_ISFINITE(optical_flow.pixel_flow_y_integral) && PX4_ISFINITE(optical_flow.pixel_flow_x_integral)) { _ekf.setOpticalFlowData(optical_flow.timestamp, &flow); } } if (range_finder_updated) { _ekf.setRangeData(range_finder.timestamp, range_finder.current_distance); } // get external vision data // if error estimates are unavailable, use parameter defined defaults if (vision_position_updated || vision_attitude_updated) { ext_vision_message ev_data; ev_data.posNED(0) = ev_pos.x; ev_data.posNED(1) = ev_pos.y; ev_data.posNED(2) = ev_pos.z; Quaternion q(ev_att.q); ev_data.quat = q; // position measurement error from parameters. TODO : use covariances from topic ev_data.posErr = _default_ev_pos_noise; ev_data.angErr = _default_ev_ang_noise; // use timestamp from external computer, clocks are synchronized when using MAVROS _ekf.setExtVisionData(vision_position_updated ? ev_pos.timestamp : ev_att.timestamp, &ev_data); } orb_check(vehicle_land_detected_sub, &vehicle_land_detected_updated); if (vehicle_land_detected_updated) { orb_copy(ORB_ID(vehicle_land_detected), vehicle_land_detected_sub, &vehicle_land_detected); _ekf.set_in_air_status(!vehicle_land_detected.landed); } // run the EKF update and output if (_ekf.update()) { matrix::Quaternion<float> q; _ekf.copy_quaternion(q.data()); float velocity[3]; _ekf.get_velocity(velocity); float gyro_rad[3]; { // generate control state data control_state_s ctrl_state = {}; float gyro_bias[3] = {}; _ekf.get_gyro_bias(gyro_bias); ctrl_state.timestamp = _replay_mode ? now : hrt_absolute_time(); gyro_rad[0] = sensors.gyro_rad[0] - gyro_bias[0]; gyro_rad[1] = sensors.gyro_rad[1] - gyro_bias[1]; gyro_rad[2] = sensors.gyro_rad[2] - gyro_bias[2]; ctrl_state.roll_rate = _lp_roll_rate.apply(gyro_rad[0]); ctrl_state.pitch_rate = _lp_pitch_rate.apply(gyro_rad[1]); ctrl_state.yaw_rate = _lp_yaw_rate.apply(gyro_rad[2]); ctrl_state.roll_rate_bias = gyro_bias[0]; ctrl_state.pitch_rate_bias = gyro_bias[1]; ctrl_state.yaw_rate_bias = gyro_bias[2]; // Velocity in body frame Vector3f v_n(velocity); matrix::Dcm<float> R_to_body(q.inversed()); Vector3f v_b = R_to_body * v_n; ctrl_state.x_vel = v_b(0); ctrl_state.y_vel = v_b(1); ctrl_state.z_vel = v_b(2); // Local Position NED float position[3]; _ekf.get_position(position); ctrl_state.x_pos = position[0]; ctrl_state.y_pos = position[1]; ctrl_state.z_pos = position[2]; // Attitude quaternion q.copyTo(ctrl_state.q); _ekf.get_quat_reset(&ctrl_state.delta_q_reset[0], &ctrl_state.quat_reset_counter); // Acceleration data matrix::Vector<float, 3> acceleration(sensors.accelerometer_m_s2); float accel_bias[3]; _ekf.get_accel_bias(accel_bias); ctrl_state.x_acc = acceleration(0) - accel_bias[0]; ctrl_state.y_acc = acceleration(1) - accel_bias[1]; ctrl_state.z_acc = acceleration(2) - accel_bias[2]; // compute lowpass filtered horizontal acceleration acceleration = R_to_body.transpose() * acceleration; _acc_hor_filt = 0.95f * _acc_hor_filt + 0.05f * sqrtf(acceleration(0) * acceleration(0) + acceleration(1) * acceleration(1)); ctrl_state.horz_acc_mag = _acc_hor_filt; ctrl_state.airspeed_valid = false; // use estimated velocity for airspeed estimate if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_MEAS) { // use measured airspeed if (PX4_ISFINITE(airspeed.indicated_airspeed_m_s) && hrt_absolute_time() - airspeed.timestamp < 1e6 && airspeed.timestamp > 0) { ctrl_state.airspeed = airspeed.indicated_airspeed_m_s; ctrl_state.airspeed_valid = true; } } else if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_EST) { if (_ekf.local_position_is_valid()) { ctrl_state.airspeed = sqrtf(velocity[0] * velocity[0] + velocity[1] * velocity[1] + velocity[2] * velocity[2]); ctrl_state.airspeed_valid = true; } } else if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_DISABLED) { // do nothing, airspeed has been declared as non-valid above, controllers // will handle this assuming always trim airspeed } // publish control state data if (_control_state_pub == nullptr) { _control_state_pub = orb_advertise(ORB_ID(control_state), &ctrl_state); } else { orb_publish(ORB_ID(control_state), _control_state_pub, &ctrl_state); } } { // generate vehicle attitude quaternion data struct vehicle_attitude_s att = {}; att.timestamp = _replay_mode ? now : hrt_absolute_time(); q.copyTo(att.q); att.rollspeed = gyro_rad[0]; att.pitchspeed = gyro_rad[1]; att.yawspeed = gyro_rad[2]; // publish vehicle attitude data if (_att_pub == nullptr) { _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &att); } else { orb_publish(ORB_ID(vehicle_attitude), _att_pub, &att); } } // generate vehicle local position data struct vehicle_local_position_s lpos = {}; float pos[3] = {}; lpos.timestamp = _replay_mode ? now : hrt_absolute_time(); // Position of body origin in local NED frame _ekf.get_position(pos); lpos.x = (_ekf.local_position_is_valid()) ? pos[0] : 0.0f; lpos.y = (_ekf.local_position_is_valid()) ? pos[1] : 0.0f; lpos.z = pos[2]; // Velocity of body origin in local NED frame (m/s) lpos.vx = velocity[0]; lpos.vy = velocity[1]; lpos.vz = velocity[2]; // TODO: better status reporting lpos.xy_valid = _ekf.local_position_is_valid(); lpos.z_valid = true; lpos.v_xy_valid = _ekf.local_position_is_valid(); lpos.v_z_valid = true; // Position of local NED origin in GPS / WGS84 frame struct map_projection_reference_s ekf_origin = {}; // true if position (x, y) is valid and has valid global reference (ref_lat, ref_lon) _ekf.get_ekf_origin(&lpos.ref_timestamp, &ekf_origin, &lpos.ref_alt); lpos.xy_global = _ekf.global_position_is_valid(); lpos.z_global = true; // true if z is valid and has valid global reference (ref_alt) lpos.ref_lat = ekf_origin.lat_rad * 180.0 / M_PI; // Reference point latitude in degrees lpos.ref_lon = ekf_origin.lon_rad * 180.0 / M_PI; // Reference point longitude in degrees // The rotation of the tangent plane vs. geographical north matrix::Eulerf euler(q); lpos.yaw = euler.psi(); float terrain_vpos; lpos.dist_bottom_valid = _ekf.get_terrain_vert_pos(&terrain_vpos); lpos.dist_bottom = terrain_vpos - pos[2]; // Distance to bottom surface (ground) in meters lpos.dist_bottom_rate = -velocity[2]; // Distance to bottom surface (ground) change rate lpos.surface_bottom_timestamp = hrt_absolute_time(); // Time when new bottom surface found // TODO: uORB definition does not define what these variables are. We have assumed them to be horizontal and vertical 1-std dev accuracy in metres Vector3f pos_var, vel_var; _ekf.get_pos_var(pos_var); _ekf.get_vel_var(vel_var); lpos.eph = sqrtf(pos_var(0) + pos_var(1)); lpos.epv = sqrtf(pos_var(2)); // get state reset information of position and velocity _ekf.get_posD_reset(&lpos.delta_z, &lpos.z_reset_counter); _ekf.get_velD_reset(&lpos.delta_vz, &lpos.vz_reset_counter); _ekf.get_posNE_reset(&lpos.delta_xy[0], &lpos.xy_reset_counter); _ekf.get_velNE_reset(&lpos.delta_vxy[0], &lpos.vxy_reset_counter); // publish vehicle local position data if (_lpos_pub == nullptr) { _lpos_pub = orb_advertise(ORB_ID(vehicle_local_position), &lpos); } else { orb_publish(ORB_ID(vehicle_local_position), _lpos_pub, &lpos); } if (_ekf.global_position_is_valid()) { // generate and publish global position data struct vehicle_global_position_s global_pos = {}; global_pos.timestamp = _replay_mode ? now : hrt_absolute_time(); global_pos.time_utc_usec = gps.time_utc_usec; // GPS UTC timestamp in microseconds double est_lat, est_lon, lat_pre_reset, lon_pre_reset; map_projection_reproject(&ekf_origin, lpos.x, lpos.y, &est_lat, &est_lon); global_pos.lat = est_lat; // Latitude in degrees global_pos.lon = est_lon; // Longitude in degrees map_projection_reproject(&ekf_origin, lpos.x - lpos.delta_xy[0], lpos.y - lpos.delta_xy[1], &lat_pre_reset, &lon_pre_reset); global_pos.delta_lat_lon[0] = est_lat - lat_pre_reset; global_pos.delta_lat_lon[1] = est_lon - lon_pre_reset; global_pos.lat_lon_reset_counter = lpos.xy_reset_counter; global_pos.alt = -pos[2] + lpos.ref_alt; // Altitude AMSL in meters _ekf.get_posD_reset(&global_pos.delta_alt, &global_pos.alt_reset_counter); // global altitude has opposite sign of local down position global_pos.delta_alt *= -1.0f; global_pos.vel_n = velocity[0]; // Ground north velocity, m/s global_pos.vel_e = velocity[1]; // Ground east velocity, m/s global_pos.vel_d = velocity[2]; // Ground downside velocity, m/s global_pos.yaw = euler.psi(); // Yaw in radians -PI..+PI. global_pos.eph = sqrtf(pos_var(0) + pos_var(1));; // Standard deviation of position estimate horizontally global_pos.epv = sqrtf(pos_var(2)); // Standard deviation of position vertically if (lpos.dist_bottom_valid) { global_pos.terrain_alt = lpos.ref_alt - terrain_vpos; // Terrain altitude in m, WGS84 global_pos.terrain_alt_valid = true; // Terrain altitude estimate is valid } else { global_pos.terrain_alt = 0.0f; // Terrain altitude in m, WGS84 global_pos.terrain_alt_valid = false; // Terrain altitude estimate is valid } // TODO use innovatun consistency check timouts to set this global_pos.dead_reckoning = false; // True if this position is estimated through dead-reckoning global_pos.pressure_alt = sensors.baro_alt_meter; // Pressure altitude AMSL (m) if (_vehicle_global_position_pub == nullptr) { _vehicle_global_position_pub = orb_advertise(ORB_ID(vehicle_global_position), &global_pos); } else { orb_publish(ORB_ID(vehicle_global_position), _vehicle_global_position_pub, &global_pos); } } } else if (_replay_mode) { // in replay mode we have to tell the replay module not to wait for an update // we do this by publishing an attitude with zero timestamp struct vehicle_attitude_s att = {}; att.timestamp = now; if (_att_pub == nullptr) { _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &att); } else { orb_publish(ORB_ID(vehicle_attitude), _att_pub, &att); } } // publish estimator status struct estimator_status_s status = {}; status.timestamp = _replay_mode ? now : hrt_absolute_time(); _ekf.get_state_delayed(status.states); _ekf.get_covariances(status.covariances); _ekf.get_gps_check_status(&status.gps_check_fail_flags); _ekf.get_control_mode(&status.control_mode_flags); _ekf.get_filter_fault_status(&status.filter_fault_flags); _ekf.get_innovation_test_status(&status.innovation_check_flags, &status.mag_test_ratio, &status.vel_test_ratio, &status.pos_test_ratio, &status.hgt_test_ratio, &status.tas_test_ratio, &status.hagl_test_ratio); bool dead_reckoning; _ekf.get_ekf_lpos_accuracy(&status.pos_horiz_accuracy, &status.pos_vert_accuracy, &dead_reckoning); _ekf.get_ekf_soln_status(&status.solution_status_flags); _ekf.get_imu_vibe_metrics(status.vibe); if (_estimator_status_pub == nullptr) { _estimator_status_pub = orb_advertise(ORB_ID(estimator_status), &status); } else { orb_publish(ORB_ID(estimator_status), _estimator_status_pub, &status); } // Publish wind estimate struct wind_estimate_s wind_estimate = {}; wind_estimate.timestamp = _replay_mode ? now : hrt_absolute_time(); wind_estimate.windspeed_north = status.states[22]; wind_estimate.windspeed_east = status.states[23]; wind_estimate.covariance_north = status.covariances[22]; wind_estimate.covariance_east = status.covariances[23]; if (_wind_pub == nullptr) { _wind_pub = orb_advertise(ORB_ID(wind_estimate), &wind_estimate); } else { orb_publish(ORB_ID(wind_estimate), _wind_pub, &wind_estimate); } // publish estimator innovation data { struct ekf2_innovations_s innovations = {}; innovations.timestamp = _replay_mode ? now : hrt_absolute_time(); _ekf.get_vel_pos_innov(&innovations.vel_pos_innov[0]); _ekf.get_mag_innov(&innovations.mag_innov[0]); _ekf.get_heading_innov(&innovations.heading_innov); _ekf.get_airspeed_innov(&innovations.airspeed_innov); _ekf.get_beta_innov(&innovations.beta_innov); _ekf.get_flow_innov(&innovations.flow_innov[0]); _ekf.get_hagl_innov(&innovations.hagl_innov); _ekf.get_vel_pos_innov_var(&innovations.vel_pos_innov_var[0]); _ekf.get_mag_innov_var(&innovations.mag_innov_var[0]); _ekf.get_heading_innov_var(&innovations.heading_innov_var); _ekf.get_airspeed_innov_var(&innovations.airspeed_innov_var); _ekf.get_beta_innov_var(&innovations.beta_innov_var); _ekf.get_flow_innov_var(&innovations.flow_innov_var[0]); _ekf.get_hagl_innov_var(&innovations.hagl_innov_var); _ekf.get_output_tracking_error(&innovations.output_tracking_error[0]); if (_estimator_innovations_pub == nullptr) { _estimator_innovations_pub = orb_advertise(ORB_ID(ekf2_innovations), &innovations); } else { orb_publish(ORB_ID(ekf2_innovations), _estimator_innovations_pub, &innovations); } } // save the declination to the EKF2_MAG_DECL parameter when a land event is detected if ((_params->mag_declination_source & (1 << 1)) && !_prev_landed && vehicle_land_detected.landed) { float decl_deg; _ekf.copy_mag_decl_deg(&decl_deg); _mag_declination_deg.set(decl_deg); } _prev_landed = vehicle_land_detected.landed; // publish ekf2_timestamps (using 0.1 ms relative timestamps) { ekf2_timestamps_s ekf2_timestamps; ekf2_timestamps.timestamp = sensors.timestamp; if (gps_updated) { // divide individually to get consistent rounding behavior ekf2_timestamps.gps_timestamp_rel = (int16_t)((int64_t)gps.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.gps_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (optical_flow_updated) { ekf2_timestamps.optical_flow_timestamp_rel = (int16_t)((int64_t)optical_flow.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.optical_flow_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (range_finder_updated) { ekf2_timestamps.distance_sensor_timestamp_rel = (int16_t)((int64_t)range_finder.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.distance_sensor_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (airspeed_updated) { ekf2_timestamps.airspeed_timestamp_rel = (int16_t)((int64_t)airspeed.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.airspeed_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (vision_position_updated) { ekf2_timestamps.vision_position_timestamp_rel = (int16_t)((int64_t)ev_pos.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.vision_position_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (vision_attitude_updated) { ekf2_timestamps.vision_attitude_timestamp_rel = (int16_t)((int64_t)ev_att.timestamp / 100 - (int64_t)ekf2_timestamps.timestamp / 100); } else { ekf2_timestamps.vision_attitude_timestamp_rel = ekf2_timestamps_s::RELATIVE_TIMESTAMP_INVALID; } if (_ekf2_timestamps_pub == nullptr) { _ekf2_timestamps_pub = orb_advertise(ORB_ID(ekf2_timestamps), &ekf2_timestamps); } else { orb_publish(ORB_ID(ekf2_timestamps), _ekf2_timestamps_pub, &ekf2_timestamps); } } // publish replay message if in replay mode bool publish_replay_message = (bool)_param_record_replay_msg.get(); if (publish_replay_message) { struct ekf2_replay_s replay = {}; replay.timestamp = now; replay.gyro_integral_dt = sensors.gyro_integral_dt; replay.accelerometer_integral_dt = sensors.accelerometer_integral_dt; replay.magnetometer_timestamp = _timestamp_mag_us; replay.baro_timestamp = _timestamp_balt_us; memcpy(replay.gyro_rad, sensors.gyro_rad, sizeof(replay.gyro_rad)); memcpy(replay.accelerometer_m_s2, sensors.accelerometer_m_s2, sizeof(replay.accelerometer_m_s2)); memcpy(replay.magnetometer_ga, sensors.magnetometer_ga, sizeof(replay.magnetometer_ga)); replay.baro_alt_meter = sensors.baro_alt_meter; // only write gps data if we had a gps update. if (gps_updated) { replay.time_usec = gps.timestamp; replay.lat = gps.lat; replay.lon = gps.lon; replay.alt = gps.alt; replay.fix_type = gps.fix_type; replay.nsats = gps.satellites_used; replay.eph = gps.eph; replay.epv = gps.epv; replay.sacc = gps.s_variance_m_s; replay.vel_m_s = gps.vel_m_s; replay.vel_n_m_s = gps.vel_n_m_s; replay.vel_e_m_s = gps.vel_e_m_s; replay.vel_d_m_s = gps.vel_d_m_s; replay.vel_ned_valid = gps.vel_ned_valid; } else { // this will tell the logging app not to bother logging any gps replay data replay.time_usec = 0; } if (optical_flow_updated) { replay.flow_timestamp = optical_flow.timestamp; replay.flow_pixel_integral[0] = optical_flow.pixel_flow_x_integral; replay.flow_pixel_integral[1] = optical_flow.pixel_flow_y_integral; replay.flow_gyro_integral[0] = optical_flow.gyro_x_rate_integral; replay.flow_gyro_integral[1] = optical_flow.gyro_y_rate_integral; replay.flow_time_integral = optical_flow.integration_timespan; replay.flow_quality = optical_flow.quality; } else { replay.flow_timestamp = 0; } if (range_finder_updated) { replay.rng_timestamp = range_finder.timestamp; replay.range_to_ground = range_finder.current_distance; } else { replay.rng_timestamp = 0; } if (airspeed_updated) { replay.asp_timestamp = airspeed.timestamp; replay.indicated_airspeed_m_s = airspeed.indicated_airspeed_m_s; replay.true_airspeed_m_s = airspeed.true_airspeed_m_s; } else { replay.asp_timestamp = 0; } if (vision_position_updated || vision_attitude_updated) { replay.ev_timestamp = vision_position_updated ? ev_pos.timestamp : ev_att.timestamp; replay.pos_ev[0] = ev_pos.x; replay.pos_ev[1] = ev_pos.y; replay.pos_ev[2] = ev_pos.z; replay.quat_ev[0] = ev_att.q[0]; replay.quat_ev[1] = ev_att.q[1]; replay.quat_ev[2] = ev_att.q[2]; replay.quat_ev[3] = ev_att.q[3]; // TODO : switch to covariances from topic later replay.pos_err = _default_ev_pos_noise; replay.ang_err = _default_ev_ang_noise; } else { replay.ev_timestamp = 0; } if (_replay_pub == nullptr) { _replay_pub = orb_advertise(ORB_ID(ekf2_replay), &replay); } else { orb_publish(ORB_ID(ekf2_replay), _replay_pub, &replay); } } } orb_unsubscribe(sensors_sub); orb_unsubscribe(gps_sub); orb_unsubscribe(airspeed_sub); orb_unsubscribe(params_sub); orb_unsubscribe(optical_flow_sub); orb_unsubscribe(range_finder_sub); orb_unsubscribe(ev_pos_sub); orb_unsubscribe(vehicle_land_detected_sub); orb_unsubscribe(status_sub); delete ekf2::instance; ekf2::instance = nullptr; }
void Ekf2::task_main() { // subscribe to relevant topics _sensors_sub = orb_subscribe(ORB_ID(sensor_combined)); _gps_sub = orb_subscribe(ORB_ID(vehicle_gps_position)); _airspeed_sub = orb_subscribe(ORB_ID(airspeed)); _params_sub = orb_subscribe(ORB_ID(parameter_update)); _optical_flow_sub = orb_subscribe(ORB_ID(optical_flow)); _range_finder_sub = orb_subscribe(ORB_ID(distance_sensor)); _ev_pos_sub = orb_subscribe(ORB_ID(vision_position_estimate)); _vehicle_land_detected_sub = orb_subscribe(ORB_ID(vehicle_land_detected)); _status_sub = orb_subscribe(ORB_ID(vehicle_status)); px4_pollfd_struct_t fds[2] = {}; fds[0].fd = _sensors_sub; fds[0].events = POLLIN; fds[1].fd = _params_sub; fds[1].events = POLLIN; // initialise parameter cache updateParams(); // initialize data structures outside of loop // because they will else not always be // properly populated sensor_combined_s sensors = {}; vehicle_gps_position_s gps = {}; airspeed_s airspeed = {}; optical_flow_s optical_flow = {}; distance_sensor_s range_finder = {}; vehicle_land_detected_s vehicle_land_detected = {}; vision_position_estimate_s ev = {}; vehicle_status_s _vehicle_status = {}; while (!_task_should_exit) { int ret = px4_poll(fds, sizeof(fds) / sizeof(fds[0]), 1000); if (ret < 0) { // Poll error, sleep and try again usleep(10000); continue; } else if (ret == 0) { // Poll timeout or no new data, do nothing continue; } if (fds[1].revents & POLLIN) { // read from param to clear updated flag struct parameter_update_s update; orb_copy(ORB_ID(parameter_update), _params_sub, &update); updateParams(); // fetch sensor data in next loop continue; } else if (!(fds[0].revents & POLLIN)) { // no new data continue; } bool gps_updated = false; bool airspeed_updated = false; bool optical_flow_updated = false; bool range_finder_updated = false; bool vehicle_land_detected_updated = false; bool vision_position_updated = false; bool vehicle_status_updated = false; orb_copy(ORB_ID(sensor_combined), _sensors_sub, &sensors); // update all other topics if they have new data orb_check(_status_sub, &vehicle_status_updated); if (vehicle_status_updated) { orb_copy(ORB_ID(vehicle_status), _status_sub, &_vehicle_status); } orb_check(_gps_sub, &gps_updated); if (gps_updated) { orb_copy(ORB_ID(vehicle_gps_position), _gps_sub, &gps); } orb_check(_airspeed_sub, &airspeed_updated); if (airspeed_updated) { orb_copy(ORB_ID(airspeed), _airspeed_sub, &airspeed); } orb_check(_optical_flow_sub, &optical_flow_updated); if (optical_flow_updated) { orb_copy(ORB_ID(optical_flow), _optical_flow_sub, &optical_flow); } orb_check(_range_finder_sub, &range_finder_updated); if (range_finder_updated) { orb_copy(ORB_ID(distance_sensor), _range_finder_sub, &range_finder); } orb_check(_ev_pos_sub, &vision_position_updated); if (vision_position_updated) { orb_copy(ORB_ID(vision_position_estimate), _ev_pos_sub, &ev); } // in replay mode we are getting the actual timestamp from the sensor topic hrt_abstime now = 0; if (_replay_mode) { now = sensors.timestamp; } else { now = hrt_absolute_time(); } // push imu data into estimator _ekf.setIMUData(now, sensors.gyro_integral_dt[0], sensors.accelerometer_integral_dt[0], &sensors.gyro_integral_rad[0], &sensors.accelerometer_integral_m_s[0]); // read mag data _ekf.setMagData(sensors.magnetometer_timestamp[0], &sensors.magnetometer_ga[0]); // read baro data _ekf.setBaroData(sensors.baro_timestamp[0], &sensors.baro_alt_meter[0]); // read gps data if available if (gps_updated) { struct gps_message gps_msg = {}; gps_msg.time_usec = gps.timestamp; gps_msg.lat = gps.lat; gps_msg.lon = gps.lon; gps_msg.alt = gps.alt; gps_msg.fix_type = gps.fix_type; gps_msg.eph = gps.eph; gps_msg.epv = gps.epv; gps_msg.sacc = gps.s_variance_m_s; gps_msg.vel_m_s = gps.vel_m_s; gps_msg.vel_ned[0] = gps.vel_n_m_s; gps_msg.vel_ned[1] = gps.vel_e_m_s; gps_msg.vel_ned[2] = gps.vel_d_m_s; gps_msg.vel_ned_valid = gps.vel_ned_valid; gps_msg.nsats = gps.satellites_used; //TODO add gdop to gps topic gps_msg.gdop = 0.0f; _ekf.setGpsData(gps.timestamp, &gps_msg); } // only set airspeed data if condition for airspeed fusion are met bool fuse_airspeed = airspeed_updated && !_vehicle_status.is_rotary_wing && _arspFusionThreshold.get() <= airspeed.true_airspeed_m_s && _arspFusionThreshold.get() >= 0.1f; if (fuse_airspeed) { float eas2tas = airspeed.true_airspeed_m_s / airspeed.indicated_airspeed_m_s; _ekf.setAirspeedData(airspeed.timestamp, &airspeed.true_airspeed_m_s, &eas2tas); } if (optical_flow_updated) { flow_message flow; flow.flowdata(0) = optical_flow.pixel_flow_x_integral; flow.flowdata(1) = optical_flow.pixel_flow_y_integral; flow.quality = optical_flow.quality; flow.gyrodata(0) = optical_flow.gyro_x_rate_integral; flow.gyrodata(1) = optical_flow.gyro_y_rate_integral; flow.gyrodata(2) = optical_flow.gyro_z_rate_integral; flow.dt = optical_flow.integration_timespan; if (PX4_ISFINITE(optical_flow.pixel_flow_y_integral) && PX4_ISFINITE(optical_flow.pixel_flow_x_integral)) { _ekf.setOpticalFlowData(optical_flow.timestamp, &flow); } } if (range_finder_updated) { _ekf.setRangeData(range_finder.timestamp, &range_finder.current_distance); } // get external vision data // if error estimates are unavailable, use parameter defined defaults if (vision_position_updated) { ext_vision_message ev_data; ev_data.posNED(0) = ev.x; ev_data.posNED(1) = ev.y; ev_data.posNED(2) = ev.z; Quaternion q(ev.q); ev_data.quat = q; // position measurement error if (ev.pos_err >= 0.001f) { ev_data.posErr = ev.pos_err; } else { ev_data.posErr = _default_ev_pos_noise; } // angle measurement error if (ev.ang_err >= 0.001f) { ev_data.angErr = ev.ang_err; } else { ev_data.angErr = _default_ev_ang_noise; } // use timestamp from external computer - requires clocks to be synchronised so may not be a good idea _ekf.setExtVisionData(ev.timestamp_computer, &ev_data); } orb_check(_vehicle_land_detected_sub, &vehicle_land_detected_updated); if (vehicle_land_detected_updated) { orb_copy(ORB_ID(vehicle_land_detected), _vehicle_land_detected_sub, &vehicle_land_detected); _ekf.set_in_air_status(!vehicle_land_detected.landed); } // run the EKF update and output if (_ekf.update()) { // generate vehicle attitude quaternion data struct vehicle_attitude_s att = {}; _ekf.copy_quaternion(att.q); matrix::Quaternion<float> q(att.q[0], att.q[1], att.q[2], att.q[3]); // generate control state data control_state_s ctrl_state = {}; float gyro_bias[3] = {}; _ekf.get_gyro_bias(gyro_bias); ctrl_state.timestamp = hrt_absolute_time(); ctrl_state.roll_rate = _lp_roll_rate.apply(sensors.gyro_rad_s[0]) - gyro_bias[0]; ctrl_state.pitch_rate = _lp_pitch_rate.apply(sensors.gyro_rad_s[1]) - gyro_bias[1]; ctrl_state.yaw_rate = _lp_yaw_rate.apply(sensors.gyro_rad_s[2]) - gyro_bias[2]; // Velocity in body frame float velocity[3]; _ekf.get_velocity(velocity); Vector3f v_n(velocity); matrix::Dcm<float> R_to_body(q.inversed()); Vector3f v_b = R_to_body * v_n; ctrl_state.x_vel = v_b(0); ctrl_state.y_vel = v_b(1); ctrl_state.z_vel = v_b(2); // Local Position NED float position[3]; _ekf.get_position(position); ctrl_state.x_pos = position[0]; ctrl_state.y_pos = position[1]; ctrl_state.z_pos = position[2]; // Attitude quaternion ctrl_state.q[0] = q(0); ctrl_state.q[1] = q(1); ctrl_state.q[2] = q(2); ctrl_state.q[3] = q(3); // Acceleration data matrix::Vector<float, 3> acceleration = {&sensors.accelerometer_m_s2[0]}; float accel_bias[3]; _ekf.get_accel_bias(accel_bias); ctrl_state.x_acc = acceleration(0) - accel_bias[0]; ctrl_state.y_acc = acceleration(1) - accel_bias[1]; ctrl_state.z_acc = acceleration(2) - accel_bias[2]; // compute lowpass filtered horizontal acceleration acceleration = R_to_body.transpose() * acceleration; _acc_hor_filt = 0.95f * _acc_hor_filt + 0.05f * sqrtf(acceleration(0) * acceleration(0) + acceleration( 1) * acceleration(1)); ctrl_state.horz_acc_mag = _acc_hor_filt; float vel[3] = {}; _ekf.get_velocity(vel); ctrl_state.airspeed_valid = false; // use estimated velocity for airspeed estimate if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_MEAS) { // use measured airspeed if (PX4_ISFINITE(airspeed.indicated_airspeed_m_s) && hrt_absolute_time() - airspeed.timestamp < 1e6 && airspeed.timestamp > 0) { ctrl_state.airspeed = airspeed.indicated_airspeed_m_s; ctrl_state.airspeed_valid = true; } } else if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_EST) { if (_ekf.local_position_is_valid()) { ctrl_state.airspeed = sqrtf(vel[0] * vel[0] + vel[1] * vel[1] + vel[2] * vel[2]); ctrl_state.airspeed_valid = true; } } else if (_airspeed_mode.get() == control_state_s::AIRSPD_MODE_DISABLED) { // do nothing, airspeed has been declared as non-valid above, controllers // will handle this assuming always trim airspeed } // publish control state data if (_control_state_pub == nullptr) { _control_state_pub = orb_advertise(ORB_ID(control_state), &ctrl_state); } else { orb_publish(ORB_ID(control_state), _control_state_pub, &ctrl_state); } // generate remaining vehicle attitude data att.timestamp = hrt_absolute_time(); matrix::Euler<float> euler(q); att.roll = euler(0); att.pitch = euler(1); att.yaw = euler(2); att.q[0] = q(0); att.q[1] = q(1); att.q[2] = q(2); att.q[3] = q(3); att.q_valid = true; att.rollspeed = sensors.gyro_rad_s[0]; att.pitchspeed = sensors.gyro_rad_s[1]; att.yawspeed = sensors.gyro_rad_s[2]; // publish vehicle attitude data if (_att_pub == nullptr) { _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &att); } else { orb_publish(ORB_ID(vehicle_attitude), _att_pub, &att); } // generate vehicle local position data struct vehicle_local_position_s lpos = {}; float pos[3] = {}; lpos.timestamp = hrt_absolute_time(); // Position of body origin in local NED frame _ekf.get_position(pos); lpos.x = pos[0]; lpos.y = pos[1]; lpos.z = pos[2]; // Velocity of body origin in local NED frame (m/s) lpos.vx = vel[0]; lpos.vy = vel[1]; lpos.vz = vel[2]; // TODO: better status reporting lpos.xy_valid = _ekf.local_position_is_valid(); lpos.z_valid = true; lpos.v_xy_valid = _ekf.local_position_is_valid(); lpos.v_z_valid = true; // Position of local NED origin in GPS / WGS84 frame struct map_projection_reference_s ekf_origin = {}; // true if position (x, y) is valid and has valid global reference (ref_lat, ref_lon) _ekf.get_ekf_origin(&lpos.ref_timestamp, &ekf_origin, &lpos.ref_alt); lpos.xy_global = _ekf.global_position_is_valid(); lpos.z_global = true; // true if z is valid and has valid global reference (ref_alt) lpos.ref_lat = ekf_origin.lat_rad * 180.0 / M_PI; // Reference point latitude in degrees lpos.ref_lon = ekf_origin.lon_rad * 180.0 / M_PI; // Reference point longitude in degrees // The rotation of the tangent plane vs. geographical north lpos.yaw = att.yaw; float terrain_vpos; lpos.dist_bottom_valid = _ekf.get_terrain_vert_pos(&terrain_vpos); lpos.dist_bottom = terrain_vpos - pos[2]; // Distance to bottom surface (ground) in meters lpos.dist_bottom_rate = -vel[2]; // Distance to bottom surface (ground) change rate lpos.surface_bottom_timestamp = hrt_absolute_time(); // Time when new bottom surface found // TODO: uORB definition does not define what these variables are. We have assumed them to be horizontal and vertical 1-std dev accuracy in metres Vector3f pos_var, vel_var; _ekf.get_pos_var(pos_var); _ekf.get_vel_var(vel_var); lpos.eph = sqrt(pos_var(0) + pos_var(1)); lpos.epv = sqrt(pos_var(2)); // publish vehicle local position data if (_lpos_pub == nullptr) { _lpos_pub = orb_advertise(ORB_ID(vehicle_local_position), &lpos); } else { orb_publish(ORB_ID(vehicle_local_position), _lpos_pub, &lpos); } // generate and publish global position data struct vehicle_global_position_s global_pos = {}; if (_ekf.global_position_is_valid()) { global_pos.timestamp = hrt_absolute_time(); // Time of this estimate, in microseconds since system start global_pos.time_utc_usec = gps.time_utc_usec; // GPS UTC timestamp in microseconds double est_lat, est_lon; map_projection_reproject(&ekf_origin, lpos.x, lpos.y, &est_lat, &est_lon); global_pos.lat = est_lat; // Latitude in degrees global_pos.lon = est_lon; // Longitude in degrees global_pos.alt = -pos[2] + lpos.ref_alt; // Altitude AMSL in meters global_pos.vel_n = vel[0]; // Ground north velocity, m/s global_pos.vel_e = vel[1]; // Ground east velocity, m/s global_pos.vel_d = vel[2]; // Ground downside velocity, m/s global_pos.yaw = euler(2); // Yaw in radians -PI..+PI. global_pos.eph = sqrt(pos_var(0) + pos_var(1));; // Standard deviation of position estimate horizontally global_pos.epv = sqrt(pos_var(2)); // Standard deviation of position vertically // TODO: implement terrain estimator global_pos.terrain_alt = 0.0f; // Terrain altitude in m, WGS84 global_pos.terrain_alt_valid = false; // Terrain altitude estimate is valid // TODO use innovatun consistency check timouts to set this global_pos.dead_reckoning = false; // True if this position is estimated through dead-reckoning global_pos.pressure_alt = sensors.baro_alt_meter[0]; // Pressure altitude AMSL (m) if (_vehicle_global_position_pub == nullptr) { _vehicle_global_position_pub = orb_advertise(ORB_ID(vehicle_global_position), &global_pos); } else { orb_publish(ORB_ID(vehicle_global_position), _vehicle_global_position_pub, &global_pos); } } } else if (_replay_mode) { // in replay mode we have to tell the replay module not to wait for an update // we do this by publishing an attitude with zero timestamp struct vehicle_attitude_s att = {}; att.timestamp = 0; if (_att_pub == nullptr) { _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &att); } else { orb_publish(ORB_ID(vehicle_attitude), _att_pub, &att); } } // publish estimator status struct estimator_status_s status = {}; status.timestamp = hrt_absolute_time(); _ekf.get_state_delayed(status.states); _ekf.get_covariances(status.covariances); _ekf.get_gps_check_status(&status.gps_check_fail_flags); _ekf.get_control_mode(&status.control_mode_flags); _ekf.get_filter_fault_status(&status.filter_fault_flags); if (_estimator_status_pub == nullptr) { _estimator_status_pub = orb_advertise(ORB_ID(estimator_status), &status); } else { orb_publish(ORB_ID(estimator_status), _estimator_status_pub, &status); } // Publish wind estimate struct wind_estimate_s wind_estimate = {}; wind_estimate.timestamp = hrt_absolute_time(); wind_estimate.windspeed_north = status.states[22]; wind_estimate.windspeed_east = status.states[23]; wind_estimate.covariance_north = status.covariances[22]; wind_estimate.covariance_east = status.covariances[23]; if (_wind_pub == nullptr) { _wind_pub = orb_advertise(ORB_ID(wind_estimate), &wind_estimate); } else { orb_publish(ORB_ID(wind_estimate), _wind_pub, &wind_estimate); } // publish estimator innovation data struct ekf2_innovations_s innovations = {}; innovations.timestamp = hrt_absolute_time(); _ekf.get_vel_pos_innov(&innovations.vel_pos_innov[0]); _ekf.get_mag_innov(&innovations.mag_innov[0]); _ekf.get_heading_innov(&innovations.heading_innov); _ekf.get_airspeed_innov(&innovations.airspeed_innov); _ekf.get_flow_innov(&innovations.flow_innov[0]); _ekf.get_hagl_innov(&innovations.hagl_innov); _ekf.get_vel_pos_innov_var(&innovations.vel_pos_innov_var[0]); _ekf.get_mag_innov_var(&innovations.mag_innov_var[0]); _ekf.get_heading_innov_var(&innovations.heading_innov_var); _ekf.get_airspeed_innov_var(&innovations.airspeed_innov_var); _ekf.get_flow_innov_var(&innovations.flow_innov_var[0]); _ekf.get_hagl_innov_var(&innovations.hagl_innov_var); if (_estimator_innovations_pub == nullptr) { _estimator_innovations_pub = orb_advertise(ORB_ID(ekf2_innovations), &innovations); } else { orb_publish(ORB_ID(ekf2_innovations), _estimator_innovations_pub, &innovations); } // save the declination to the EKF2_MAG_DECL parameter when a land event is detected if ((_params->mag_declination_source & (1 << 1)) && !_prev_landed && vehicle_land_detected.landed) { float decl_deg; _ekf.copy_mag_decl_deg(&decl_deg); _mag_declination_deg.set(decl_deg); } _prev_landed = vehicle_land_detected.landed; // publish replay message if in replay mode bool publish_replay_message = (bool)_param_record_replay_msg.get(); if (publish_replay_message) { struct ekf2_replay_s replay = {}; replay.time_ref = now; replay.gyro_integral_dt = sensors.gyro_integral_dt[0]; replay.accelerometer_integral_dt = sensors.accelerometer_integral_dt[0]; replay.magnetometer_timestamp = sensors.magnetometer_timestamp[0]; replay.baro_timestamp = sensors.baro_timestamp[0]; memcpy(&replay.gyro_integral_rad[0], &sensors.gyro_integral_rad[0], sizeof(replay.gyro_integral_rad)); memcpy(&replay.accelerometer_integral_m_s[0], &sensors.accelerometer_integral_m_s[0], sizeof(replay.accelerometer_integral_m_s)); memcpy(&replay.magnetometer_ga[0], &sensors.magnetometer_ga[0], sizeof(replay.magnetometer_ga)); replay.baro_alt_meter = sensors.baro_alt_meter[0]; // only write gps data if we had a gps update. if (gps_updated) { replay.time_usec = gps.timestamp; replay.time_usec_vel = gps.timestamp; replay.lat = gps.lat; replay.lon = gps.lon; replay.alt = gps.alt; replay.fix_type = gps.fix_type; replay.nsats = gps.satellites_used; replay.eph = gps.eph; replay.epv = gps.epv; replay.sacc = gps.s_variance_m_s; replay.vel_m_s = gps.vel_m_s; replay.vel_n_m_s = gps.vel_n_m_s; replay.vel_e_m_s = gps.vel_e_m_s; replay.vel_d_m_s = gps.vel_d_m_s; replay.vel_ned_valid = gps.vel_ned_valid; } else { // this will tell the logging app not to bother logging any gps replay data replay.time_usec = 0; } if (optical_flow_updated) { replay.flow_timestamp = optical_flow.timestamp; replay.flow_pixel_integral[0] = optical_flow.pixel_flow_x_integral; replay.flow_pixel_integral[1] = optical_flow.pixel_flow_y_integral; replay.flow_gyro_integral[0] = optical_flow.gyro_x_rate_integral; replay.flow_gyro_integral[1] = optical_flow.gyro_y_rate_integral; replay.flow_time_integral = optical_flow.integration_timespan; replay.flow_quality = optical_flow.quality; } else { replay.flow_timestamp = 0; } if (range_finder_updated) { replay.rng_timestamp = range_finder.timestamp; replay.range_to_ground = range_finder.current_distance; } else { replay.rng_timestamp = 0; } if (airspeed_updated) { replay.asp_timestamp = airspeed.timestamp; replay.indicated_airspeed_m_s = airspeed.indicated_airspeed_m_s; replay.true_airspeed_m_s = airspeed.true_airspeed_m_s; } else { replay.asp_timestamp = 0; } if (vision_position_updated) { replay.ev_timestamp = ev.timestamp_computer; replay.pos_ev[0] = ev.x; replay.pos_ev[1] = ev.y; replay.pos_ev[2] = ev.z; replay.quat_ev[0] = ev.q[0]; replay.quat_ev[1] = ev.q[1]; replay.quat_ev[2] = ev.q[2]; replay.quat_ev[3] = ev.q[3]; replay.pos_err = ev.pos_err; replay.ang_err = ev.ang_err; } else { replay.ev_timestamp = 0; } if (_replay_pub == nullptr) { _replay_pub = orb_advertise(ORB_ID(ekf2_replay), &replay); } else { orb_publish(ORB_ID(ekf2_replay), _replay_pub, &replay); } } } delete ekf2::instance; ekf2::instance = nullptr; }